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In-Plane Cracking Behavior and Ultimate Strength for 2D Woven and Braided Melt-Infiltrated SiC/SiC Composites Tensile Loaded in Off-Axis Fiber Directions Gregory N. Morscher; Ohio Aerospace Institute, Cleveland, OH Hee Mann Yun; Matech GSM, CA James A. DiCarlo; NASA Glenn Research Center, Cleveland, OH ABSTRACT The tensile mechanical properties of ceramic matrix composites (CMC) in directions off
the primary axes of the reinforcing fibers are important for architectural design of CMC
components that are subjected to multi-axial stress states. In this study, 2D-woven melt-
infiltrated (MI) SiC/SiC composite panels with balanced fiber content in the 0o and 90o
directions were tensile loaded in-plane in the 0o direction and at 45o to this direction. In
addition, a 2D triaxially-braided MI composite panel with balanced fiber content in the
+/- 67o bias directions and reduced fiber content in the axial direction was tensile loaded
perpendicular to the axial direction tows (i.e., 23o from the bias fibers). Stress-strain
behavior, acoustic emission, and optical microscopy were used to quantify stress-
dependent matrix cracking and ultimate strength in the panels. It was observed that both
off-axis loaded panels displayed higher composite onset stresses for through-thickness
matrix cracking than the 2D-woven 0/90 panels loaded in the primary 0o direction. These
improvements for off-axis cracking strength can in part be attributed to higher effective
fiber fractions in the loading direction, which in turn reduces internal stresses on critical
matrix flaws for a given composite stress. Also for the 0/90 panel loaded in the 45o
direction, an improved distribution of matrix flaws existed due to the absence of fiber
tows perpendicular to the loading direction. In addition, for the +67/0/-67 braided panel,
the axial tows perpendicular to the loading direction were not only low in volume
fraction, but were also were well separated from one another. Both off-axis oriented
panels also showed relatively good ultimate tensile strength when compared to other off-
axis oriented composites in the literature, both on an absolute strength basis as well as
when normalized by the average fiber strength within the composites. Initial implications
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are discussed for constituent and architecture design to improve the directional cracking
of SiC/SiC CMC components with MI matrices.
INTRODUCTION The tensile mechanical properties of continuous fiber-reinforced ceramic matrix
composites (CMC) vary according to the orientation of fibers with respect to the loading
axis. CMC mechanical properties are typically measured for tensile stresses in a
direction parallel to one of the primary fiber axes, which generally results in desirable
linear stress-strain behavior, a high stress for deviation from linearity or DFLS (also
referred to as proportional limit stress), and fiber-pullout mechanisms that lead to
graceful failure and high ultimate tensile strength or UTS [1]. This is the case because
the high-modulus fibers are oriented to carry much of the tensile load applied to the
composite prior to and after the DFLS point, which is caused by the development of
transverse through-thickness matrix cracks (TTMC) in the CMC. However, when loaded
in a direction at a significant angle to the primary fiber axes, large reductions in key
CMC design properties can occur such as low DFLS and UTS [2]. Whereas on-axis
properties are strongly dependent on the fiber properties, off-axis properties are strongly
dependent on the matrix properties, particularly their stiffness and load-carrying ability
which is typically related to their porosity content. For example, when CMC with highly
porous oxide matrices were tested off-axis, non-linear and relatively weak stress-strain
behavior was observed because the porous matrix could not carry significant load [3].
But when the matrix stiffness and load-carrying ability was increased via sintering of the
porous matrix, higher DFL stresses and ultimate strengths were obtained, but still not as
high as the on-axis value. .
For CMC structural applications, high stresses for generation of TTMC are
generally desired in all directions. This not only allows maintenance of composite
modulus and thermal conductivity to high stresses, but also results in greater composite
life which is particularly important for CMC with non-oxide constituents that can be
degraded by environmental permeability into through-thickness matrix cracks. To
achieve these high cracking stresses, high-stiffness low-porosity matrices are generally
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preferred, which can also help to improve the CMC creep-rupture resistance and thermal
conductivity. One such CMC system is the melt-infiltrated (MI) SiC matrix system
reinforced by the Sylramic-iBN SiC fiber that is near-stoichiometric in composition and
contains a thin in-situ grown BN layer on its surface [4]. This SiC/SiC composite system
is typically processed by taking a woven or braided fiber-preform, coating the fibers with
another thin BN layer by chemical vapor infiltration (CVI), and then forming an initial
SiC matrix by CVI. The remaining matrix porosity is then filled with slurry of SiC
particles. After drying the slurry-infiltrated perform, final matrix formation is by melt
infiltration (MI) of liquid Si which fills nearly all of the large pores in the structure,
leaving ~5% closed porosity.
The primary objective of this study was to measure and analyze the off-axis in-
plane tensile stress-strain behavior of five thin-walled panels with the MI Sylramic-
iBN/SiC system and two different basic fiber architectures, A and B. Four panels with
architecture A, consisting of a 2D-woven fabric lay-up with balanced fiber content in the
0o and 90o directions, were tensile loaded in the 0o direction (Panels A1-A3) and at 45o to
this direction (Panel A4). This balanced 2D 0/90 architecture is often used for the
fabrication of thin-walled CMC components with large radii-of-curvature. Another panel
with architecture B (Panel B1), consisting of a 2D triaxially-braided architecture with
balanced fiber content in the +/- 67o bias directions and reduced fiber content in the axial
direction, was tensile loaded perpendicular to the axial direction (i.e., 23o from the bias
fibers). Again, this 2D tri-axially braided architecture is often used for the fabrication of
thin-walled CMC components with small radii-of-curvature. Thus besides scientific
value, tensile testing of these panels in the primary fiber axis as well as in the off-axis
directions should also have technical value in that it is a first step in understanding the
mechanical and cracking effects of 2D fiber architectures and multi-directional stresses,
such as thermal stresses, in these components. The primary room temperature properties
of interest were the elastic modulus, the DFLS as measured by two off-set methods, the
UTS, and the matrix cracking behavior as monitored by acoustic emission. Initial
implications are discussed for architecture design to model and improve the directional
cracking strengths of SiC/SiC CMC components with MI matrices.
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EXPERIMENTAL For this study, four panels with architecture A were fabricated by cutting 150 x
225 mm plies from a 2D-woven 0/90 Sylramic SiC fabric* with a five-harness satin
weave and balanced tow ends per cm (epcm) in the 0o and 90o directions. Each single
tow consisted of ~800 fibers with a 10 μm average diameter. For Panels A1 and A4, the
fabric had 8.7 single tow epcm; but the plies were cut along the 0o and 90o directions for
Panel A1 and at 45o to the orthogonal directions for Panel A4. For Panels A2 and A3, the
plies were cut along the 0o and 90o directions; but the fabric had 7.9 single tow epcm for
Panel A2 and 3.95 double tow epcm for Panel A3. For each A-type panel, eight plies
were then stacked and converted to Sylramic-iBN* fiber at NASA Glenn [5]. The 2D
Sylramic-iBN stacks were then sent to GE Composites, Newark, DE, where they went
through typical MI processing: CVI BN fiber coating, CVI SiC initial matrix, water-
based slurry SiC particle infiltration, drying, and liquid-Si infiltration [4].
For Panel B1, the architecture was first formed by creating a four-layer 0/+67 tri-
axial braid on a 50 mm diameter tubular mandrel. Approximately 23% of the fibers were
in the axial direction and 77% of the fibers were in the bias direction at an angle of ~ 67o
to the axial fibers. Two as-produced Sylramic fiber tows were combined in the axial and
bias directions. A 75 mm length of the tubular architecture was then removed from the
mandrel and laid flat to form a 75 mm x ~150 mm rectangular preform, which was
converted to the Sylramic-iBN fibers at NASA and then into a CMC panel with typical
MI processing at GE composites.
Tensile 150-mm long dogbone specimens with a contoured gage section (12.7
mm width in grip region and 10 mm width in gage region) were machined from each
panel. Architecture, thickness, and total fiber volume fraction for all tested specimens
from the five panels are listed in Table 1. For Panel A1, A2, and A3 specimens, the
testing direction was along the primary or 0o direction; but for Panel A4, testing was at
45o to the 0o and 90o directions of the original fabric as shown in Fig. 1a. For the Panel B
___________________________ * The Sylramic fibers of this study were originally produced by Dow Corning, Midland, MI and were woven into fabric at Albany International Techniweave, Rochester, NH.. Both the Sylramic and Sylramic-iBN SiC fibers are currently produced at ATK COI Ceramics, San Diego, CA.
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specimens, Fig. 1b shows that the testing direction was perpendicular to the axial or 0o
fiber direction, or along the “hoop” direction of the original tubular architecture. Thus
for both off-axis panels of this study, the tensile loading direction was symmetrically
located between the two primary fiber directions that contained equal volume fractions.
Tensile unload-reload hysteresis tests were performed on the dogbone specimens
using a universal testing machine (Model 8562, Instron, Ltd., Canton, Mass.) with
acoustic emission (AE) monitoring as described in references 6 and 7. A clip-on strain
gage (25.4 mm gage, 0.25% strain) was used to measure strain in the gage section. A
Fracture Wave Detector by Digital Wave Corporation (Englewood, CO) was used to
monitor AE. Three wide-band (B1025, Digital Wave Corporation) AE sensors were
mounted on the specimens. Two sensors were placed above and below the gage section
approximately 50 mm apart from one another. The third sensor was placed between the
other two sensors in the middle of the gage section. Only events which triggered the
middle sensor were used in the analysis, i.e., only events which occurred in the gage
section.
The tested specimens were cut and polished along the loading-direction in order
to measure transverse matrix cracks optically. The polished specimens had to be plasma
etched (CF4 at 500 Watts for 30 minutes) in order to enhance the matrix cracks in the
CVI SiC. Matrix cracks were counted over lengths of approximately 10 mm in order to
obtain a matrix crack density.
RESULTS The room-temperature tensile stress-strain curves for the off-axis oriented
SiC/SiC Panels A4 and B1 and for the orthogonal-oriented 2D woven SiC/SiC Panels
A1-A3 are shown in Figure 2. Hysteresis loops used for residual stress determination
have been eliminated from these curves except for a braided Panel B1 specimen which is
given as an example in Figure 2. Average values for such key mechanical properties as
initial elastic modulus E, UTS, and residual stress on matrix are listed in Table I. As
shown in Figure 3, the offset strain construct method [8] was also used to determine the
DFL stress (DFLS). It consists of drawing a line with the same slope as the initial elastic
modulus, but offset by some amount of positive strain, where the DFLS would be
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determined by the intersection of that curve with the stress-strain curve. Typical offset-
strain values used are 0.005% [9] and 0.002% [10]. As indicated in Table II, both values
were determined in this study.
From Table I, it can be seen that in-plane E values are similar for all the panels
with the exception of the double-tow 5HS woven composite (Panel A3). This suggests
that for this general SiC/SiC system, in-plane elastic modulus is not strongly dependent
on 2D fiber architectures or on tensile loading direction. For in-plane UTS, the 2D-
woven 0/90 panels aligned in the primary fiber axes are of course the strongest since they
were tested parallel to the fiber direction. Nevertheless, the braided panel with over
three-quarters of the fibers oriented 23o from the loading-axis, displayed a high in-plane
UTS; whereas the 45/45 panel displayed a relatively low UTS. But perhaps the most
striking mechanical results were the high in-plane DFLS values for both the braided and
45/45 panels.
These high DFLS results are confirmed in Figure 4 and Table II by the higher
stress ranges over which AE was recorded for initiation of matrix cracking in the off-axis
panels. In Figure 4, the AE activity versus applied CMC stress is plotted as normalized
cumulative AE energy, which is the cumulative AE energy of each AE event up to a
given event divided by the total AE energy of all the events. For the MI SiC/SiC system,
it has been shown [7] that this type of plot represents a good relative distribution of
transverse or thru-thickness matrix cracking. In addition, multiplying the final matrix
crack density, measured from polished sections after failure, by the normalized
cumulative AE energy is a very good estimate of the actual stress-dependent matrix crack
density versus applied CMC stress. The measured matrix crack densities at failure are
shown in Table II and the estimated matrix crack density with stress in Figure 5. The
difference in the shape of the matrix crack distribution between the double-tow and
single-tow 2D woven composites is hypothesized to be due to the greater concentration
and longer lengths of back-to-back 90o minicomposites (see Discussion). Two different
matrix crack distributions are evident for the two different off-axis loaded specimens.
The 45/45 specimen has a very steep curve, whereas the braided specimens were similar
in shape to the single-tow 2D composites. Neither off-axis composite appears to have
reached matrix crack saturation since a decrease in the rate of AE activity was never
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achieved at higher stresses. It is also interesting to note that at a composite stress of 200
MPa (29 ksi), the off-axis tested braided specimens had little or no cracks; whereas the
double-tow 2D woven composites had ~5 through-thickness matrix cracks (TTMC) per
mm.
For this study, several AE criteria were used to evaluate key stress levels near
initiation of matrix cracking since these values typically represent upper design limits
beyond which CMC moduli and axial thermal conductivity irreversibly decrease and the
possibility exists for adverse environmental effects for SiC/SiC composites [11]. These
stress levels, which are indicated in Figure 6 and Table II, are associated with (1) the first
AE event, (2) the first loud AE event which is defined as an AE event with an energy of at
least one tenth the highest energy event not corresponding to failure, and (3) the effective
AE onset event which is determined by extrapolation of the high energy noise distribution
down to the zero noise axis. It is evident in Table II that except for the first AE event, the
other two stress measures for matrix cracking are significantly higher for the off-axis
specimens than the on-axis specimens. Underlying mechanisms and technical
significance for these stress levels will be discussed in the following sections.
ANALYSIS AND DISCUSSION
The effect of architecture and stress orientation on matrix cracking (or DFLS) and
UTS are key properties that need to be understood for applications using MI SiC/SiC
composites under multi-axial stress states. In the following sections, the results in
Figures 2 and 4 and in Tables I and II will be mechanistically analyzed and compared to
other data in the literature to better understand their scientific and technical significance.
Matrix Cracking in 0/90 2D-Woven Composites Tested in 0o Direction A variety of microscopic studies using on-axis tensile stresses on 2D-woven 0/90
CMC panels have shown that at lower stresses, initial transverse matrix cracks are usually
either “tunnel” microcracks [12], which occur in the 90o minicomposites* oriented
* For the CMC of this study, a minicomposite consists of a single multi-fiber tow, the CVI BN interphase coating, and the initial CVI SiC matrix coating associated with tow.
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perpendicular to the 0o loading-axis, and/or non-steady-state microcracks that are
partially-bridged due to sufficient fiber-traction in the matrix crack wake to stop matrix
crack propagation through-thickness. At higher stresses, these microcracks propagate
through-thickness or link up with other microcracks to form TTMC over a range of stress
levels.
AE methodologies have been successfully used to not only quantify but also to
understand and model the occurrence and stress-strain effects of microcrack and TTMC
behavior. Initial low energy events generally correspond to tunnel microcrack formation
in 90o minicomposites perpendicular to the stress direction. High energy events, those in
the upper logarithmic decade of energy, correspond to either large microcracks and/or
TTMC [13]. For 2D-woven 0/90 MI SiC/SiC panels tested in the 0o direction, it has been
demonstrated that the stress distribution for TTMC is controlled both by (1) the size
distribution of 90o minicomposites perpendicular to the load-bearing 0o minicomposites,
and (2) by the in-situ stress in the region of the composite outside of the load-bearing 0o
minicomposite, i.e., the portion of the composite composed of 90o minicomposites and
MI matrix [7, 14]. For panels fabricated from the random lay-up of standard single-tow
woven fabric plies, the size distribution of 90o minicomposites can crudely vary between
the size of individual 90o minicomposites to the size of two 90o minicomposites that
happen to be adjacent to one another. Whenever this back-to-back tow circumstance
exists, the effective width of an unbridged tunnel crack would be approximately twice the
crack width of a single minicomposite. This characteristic of back-to-back individual 90o
minicomposites is much more common in the double-tow woven 3.95 epcm composite
panel compared to single-tow woven panels. There are not only more regions of multiple
90o minicomposites, but also the length of these regions (distance the tow is woven over
four tows before it is woven under the fifth tow in the five-harness satin architecture)
would be approximately twice the length of single-tow woven composites for the five-
harness satin weave since the epcm of the double-tow CMC was one-half that of the
single-tow CMC. As a result, as shown in Figure 4, the double-tow woven panel displays
the lowest onset stress and smallest stress distribution for TTMC in the on-axis panels.
In an effort to model architectural effects on the onset of through-thickness matrix
cracking in 2D-woven 0/90 SiC/SiC composites tested in the 0o direction, a previous
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study [7] has examined the important microstructural factors affecting the internal
stresses on the 90o minicomposites since these appear to be the most critical flaws within
the matrix that eventually cause TTMC. Two important factors were identified: (1) a
built-in residual stress on the matrix and (2) the applied composite stress as modified by
load shared by the 0o minicomposites. As such, one can estimate the stress on the matrix
region containing the 90 minicomposites (= minimatrix) by the following simple rule of
mixtures relationship [7]:
(1)
Here σc is the applied composite stress, σth is the residual stress in the matrix (Table I); Ec
is the measured composite elastic modulus from the σ/ε curve (Table I); fmini is the
volume fraction of the 0o minicomposites in the loading direction (typically ~ 2 times the
fiber content in the 0o direction); and Emini is the effective modulus of these 0o
minicomposites. Thus the stress on the 90 minicomposites can be reduced by increasing
a compressive residual stress on the matrix and/or by increasing fmini . As shown in Table
1, one benefit of the MI SiC/SiC system is a compressive residual stress on the as-
fabricated matrix, but this stress did not vary much with the 2D architectures of this
study. The exact source of this stress is not completely understood, but probably can be
related to the silicon content in the matrix and the composite fabrication conditions. On
the other hand, fiber content in the 0o or primary fiber direction, fprimary, can be increased
to a large degree for the MI SiC/SiC system which in turn should increase the composite
stress for onset of TTMC. That this latter mechanism can indeed be utilized is seen in
Fig. 7 which plots as open circles the AE onset cracking strength as function of fprimary for
the 0o-loaded 0/90 MI SiC/SiC composites of this study and a previous study [7].
Matrix Cracking in 0/90 2D-Woven Composites Tested in 45o Direction
The stress-distribution for matrix cracking in the 45/45 off-axis Panel A4 differs
considerably from those of 0/90 composites tested in an orthogonal direction. First AE
events show that some small microcracks were formed at low stresses in the 45/45
composite (Table II), the source of which have not been determined for certain. There
( )⎟⎟⎠
⎞⎜⎜⎝
⎛−
−+=
i
iic
c
thcimatrix f
EfEE min
minminmin 1
σσσ
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was considerable porosity in one thick matrix region between the outer two plies (Figure
8) which could have been one source. Most notably, there was also a very narrow stress-
distribution for TTMC (Figure 4), which would correspond to a large population (high
Weibull modulus) of flaws and/or microcracks that propagate through-thickness at and
slightly above the matrix cracking stress. The important fact is that this composite (Panel
A4) displayed a higher onset stress for TTMC than its theoretically equivalent 0/90
composite (Panel A1) loaded along its primary fiber axis. It is suggested that the higher
matrix cracking stress and narrow stress-distribution for matrix cracking for this system is
primarily due to a lack of minicomposites perpendicular to the direction of stress so that
higher stresses are required for tunnel crack propagation. There is also the possibility
that the 45/45 Panel A4 had a higher effective fraction of fibers carrying load in the
testing direction, which in turn would have reduced internal matrix stresses on the tunnel
cracks for a given applied composite stress.
Matrix Cracking in 0/+67 2D-Braided Composite Tested in the Hoop Direction
For the triaxially braided specimen, approximately 77% of the fibers, or a total
fiber fraction of 0.26, were oriented 23o from the loading axis. This fraction is effectively
higher than that of the 2D-woven composites loaded in the primary fiber direction, and
thus appears to be one cause for the higher matrix cracking stress for the braided
composite. As described above for the 0/90 composites, matrix cracks emanate from the
region outside of the load-bearing minicomposites, e.g., from the minicomposites
oriented 90o to the loading axis. The same type of analysis can be applied here to the
braided composites to determine if the stress ranges in the TTMC flaw-source regions
(axial tow minicomposites, see Figure 1) of the matrix are similar to standard 2D-woven
0/90 composites oriented in one of the orthogonal directions.
Assuming the applicability of Eq. 1, there is a question as to how to approximate
Emini since the fibers are oriented at an angle to the loading axis. One limit would be to
assume that the bias minicomposites would act as if they were in parallel, since there was
the same fraction of minicomposites +23o as there are -23o from the tensile axis. The
other extreme would be to assume that the modulus of a minicomposite at an angle to the
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( ) ( ) ( ) ( )θθθν
θθ
4
2
22
1
12
12
4
1
sin1cossin21cos11
EEGEE+⎟⎟
⎠
⎞⎜⎜⎝
⎛−+=
loading axis would behave similar to a unidirectional ply oriented at an angle, and could
therefore be estimated from laminate theory [15]:
(2)
where subscript 1 refers to the 0o orientation of a minicomposite, subscript 2 refers to the
transverse direction or 90o orientation of a minicomposite, and θ refers to the orientation
of the loading direction off the 0o fiber axis. G12 is the bulk modulus and ν12 is the
Poisson’s ratio.
To determine the effect of orientation, Eθ was determined for the 23o fiber
orientation case relative to the value of E1 (360 GPa for the braided composite#). E2 is
unknown for these minicomposites, but a conservative estimate would be 100 GPa, which
would be on the low-end of elastic-moduli estimated for 90o minicomposites in CVI SiC
matrix composites [16]. ν12 was assumed to be 0.15 and G12 was estimated from the
simple isotropic relationship E1/2 (1+ν12). Based on these simple assumptions Eθ/E1 =
0.943, a minor effect. Figure 9 shows the estimated matrix crack density versus
minimatrix stress for both cases in comparison to the 2D composites. The “lower bound”
assumes the minicomposites behave the same as parallel minicomposites and Emini is
determined from rule of mixtures based on the fractional content of fiber, BN, and CVI
SiC. The “upper bound” refers to a reduced Emini from Equation 2. There is only a small
difference in minimatrix stress for the two extremes and they compare well with the
composites loaded in the orthogonal direction. From this it would appear that matrix
cracking in the braided composites is controlled by the stress acting on the axial
minicomposites oriented perpendicular to the loading axis in the same manner as the 2D-
woven 0/90 composites with single tows. However, in order to increase fiber volume
fraction, the 0+67 braided composites were braided with two (double) tows woven
together for both the axial and bias fibers. But there were a smaller fraction of
minicomposites oriented perpendicular to the loading axis for the braided composites
compared to the 2D-woven 0/90 composites. Also, the perpendicular minicomposites of # The fractional content of fiber, BN, and CVI SiC was 0.32, 0.07, and 0.25, respectively. The fractional contents of the other composites were very similar to the data already reported in reference 7. fmini for the bias fibers of the braided composites was 0.54 compared to ~ 0.36 for the orthogonal composites.
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the braided composites do not contact one another (Figure 10) and form back-to-back
minicomposites as is the case for the 2D-woven 0/90 double tow composites. These two
factors are probably the reason for the cracking behavior of the braided composite being
more in line with that of the single tow woven composites and not the double tow woven
composites. Figure 7 compares the effect of effective fiber fraction in the loading
direction on AE onset stress for all the MI SiC/SiC composites studied to date with 2D
woven and braided architectures and with minicomposites oriented perpendicular to the
loading direction.
Ultimate Strength for Off-Axis Panels The ultimate strengths of the panels loaded off-axis were generally less than those
for panels tested in a primary fiber direction. This result is to be expected since the fibers
were not aligned in the direction of applied stress and are subject to local bending and
shear within a matrix crack. At this point, it is important to discuss the response of the
different types of CMCs to off-axis loading.
CMC mechanical behavior has been defined as “matrix dominated” (Class III)
and “fiber dominated” (Class II) [2, 17]. For matrix-dominated composites (e.g., SiC
fiber-reinforced glass ceramic or SiC matrix composites), initial loads are shared by an
uncracked matrix and the fibers. Therefore elastic properties are heavily influenced by
the elastic properties of the matrix. Nonlinearity in the stress strain curve is caused by
transverse matrix cracks (cracks perpendicular to the applied load) due to interface
debonding and fiber sliding resulting in fiber pullout within the matrix crack and matrix
crack opening. Transverse matrix cracking occurs for both on-axis and off-axis loading
of composites.
For fiber-dominated composites (e.g., porous oxide/oxide, C/C, or C/SiC
composites), the matrix carries little load due to the fact that the matrix is porous or
heavily microcracked, and the mechanical properties are controlled by the fiber
(architecture) response to loading. When loaded on-axis, elastic moduli are typically only
slightly larger than f(0o) x Ef, and there is only minor nonlinearity to the stress strain
curve since the matrix is highly porous and/or a high damage condition already exists in
the matrix. When loaded in the off-axis, there is significant nonlinearity in stress strain
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behavior beginning near zero stress due to the absence of parallel fibers in the loading
direction. More damage is created in the composite due to shear band formation, fiber-
rearrangement, inter-ply delamination, and fiber “scissoring”. This results in high
ultimate strains as long as the fibers can withstand the tensile and bending forces, but low
ultimate strengths due to these combined forces on the fibers. This low off-axis UTS
behavior for these fiber-dominated composites may be a limitation for certain
applications.
The Sylramic-iBN composites are an excellent example of matrix-dominated
composites and how off-axis properties can be maximized which may be important for
future applications. To demonstrate this, the ultimate tensile strength data from the
composites tested in this study (see Table I) can be compared to UTS data in the literature
for a variety of fiber-dominated and matrix-dominated 2D-woven, braided, and cross-
plied ceramic and polymer composites that were tested in a primary fiber direction as
well as in an off-axis direction. Descriptions of these composites and their ultimate
properties are listed in Table III for 0/90 composites tested in the 0 and 45/45 direction
and in Table IV for 0/90 and braided composites tested at multiple angles. These
composites included 2D plain-woven carbon fiber reinforced epoxy [18], 2D triaxially
braided carbon fiber reinforced epoxy [19], 2D eight-harness satin woven Al2O3-fiber
reinforced porous oxide matrix (mullite) composites [20], Nicalon (Nippon Carbon,
Japan) fiber reinforced carbon matrix [2, 21], Nicalon fiber reinforced glass matrix
composites [2,22], Nicalon fiber reinforced CVI SiC matrix composites [2, 21], carbon
fiber reinforced carbon matrix composites [17, 21], and 2D five-harness satin woven Hi-
Nicalon (Nippon Carbon, Japan) and Sylramic fiber reinforced MI composites [23].
It is difficult to compare all of the off-axis UTS data on an absolute basis since
composites vary considerably in fiber volume fractions, in-situ strength properties of the
fibers, interfacial sliding stress, and fiber bending stiffness, which is dependent on fiber
modulus and diameter. However, when comparing the 45/45-direction UTS of 0/90
composites, the matrix-dominated SiC composites, whether reinforced by Nicalon, Hi-
Nicalon, Sylramic, or Sylramic-iBN SiC fibers (see Tables I and III), exhibited the best
off-axis UTS values (158 to 242 MPa) compared to the fiber-dominated composites (all <
100 MPa) regardless of fiber-type.
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To crudely estimate the general effect of composite-type and off-axis testing
direction on effective fiber strength or load-carrying ability, one can eliminate the fiber
tensile strength and volume fraction effects from the strength data by normalizing the off-
axis UTS data of Tables I, III, and IV using the following relationship:
Normalized Effective Fiber Strength = (σult off-axis / σult 0) (f0 / f *off-axis) (3)*
where σult 0 and f0 refers, respectively, to the UTS and fraction of fibers in the primary
fiber direction; and σult off-axis and f*off-axis refers, respectively, to the UTS and effective
load-bearing fraction of fibers in the off-axis direction. It can be assumed for 0/90
composites when loaded symmetric to the primary fiber directions, e.g., 45/45, that both
fiber axes are carrying load, so that f*off-axis = 2 f0 . For non-symmetric loading, it can be
assumed that the fibers in the axis at the greatest angle to the loading direction will
fracture first, debond, and/or pull apart, leaving the other primary axis fibers to control
UTS, so that f*off-axis equals f0 of the remaining fibers. For braided composites,
specimens tested in the hoop direction were compared to specimens from the same panel
tested in the axial direction (C/epoxy – Table IV) or to 0/90 specimens tested in the 0
direction (Syl-iBN MI – Table I).
Based on these assumptions and Eq. 3, Fig. 11 shows the normalized fiber
strength results as a function of test angle using the UTS data from Tables I, III, and IV.
Again the four high-modulus SiC-based matrix composites exhibit the best relative
retention of fiber strength. For the fiber-dominated or low-modulus matrix composites,
C/epoxy, Al2O3/mullite, Nic/C, C/C, and C/SiC, there was excellent correlation at 45o,
but poorer off-axis strengths. The two matrix-dominated glass-ceramic matrix
composites were in between the fiber-dominated and SiC-based matrix-dominated
composites probably due to the lower modulus of the glass-ceramic matrix compared to
CVI and MI SiC matrices. It is significant that the braided and 0/90o C/epoxy data from
* Note that in Equation 3, the ellipsoid character of off-axis oriented fibers in the plane of failure was not taken into account. A more exhaustive and complicated analysis would require not only the angle, but the nature of fiber/matrix sliding which is not well understood [2], the matrix crack opening and the degree of fiber straightening. From an engineering and design standpoint, the simple analysis performed here is considered to be more straightforward and useful.
15
different studies over the range of angles tested correlate with one another, justifying
some of the crude assumptions made above.
For fiber orientations 25 to 45o off the loading axis, the relative stress-carrying
ability of the Syl-iBN fibers in high-modulus SiC-based matrices ranged from 50% to
30% of the fiber strength, respectively, when oriented in the primary 0o direction.
Though the relative stress-carrying ability decreased with angle, it was still far superior to
the fiber-dominated systems (50% greater relative stress at 25o and 100% greater relative
stress at 45o). This is an important design consideration for composite and architecture
selection when appreciable off-axis loading applications are pursued.
Note that the Nic/CVI SiC [2, 21] composites had the highest relative off-axis
strength. As discussed above, the Eq. 3 analysis does not account for such material
properties as interfacial sliding stress and fiber bending stiffness, which will affect the
mechanics of fiber fracture when aligned at an angle within a transverse matrix crack.
The absolute off-axis strengths of the NiC/CVI SiC composites were similar to the
HN/MI and Sylramic/MI and less than the Syl-iBN / MI composites. Also, σult0 of the
Nic/CVI SiC composites were poor indicating a low in-situ (after processing) fiber
strength in comparison to the other SiC/SiC composites, possibly resulting in higher than
expected normalized fiber strength results. Another possibility is that the beneficial
effects of a lower fiber modulus and interfacial sliding stress are becoming evident for the
Nicalon composites. Nevertheless, it is suggested that the two lines in Figure 11
represent, albeit crudely, off-axis UTS for matrix-dominated and fiber-dominated CMC.
These relationships can be used by designers as a “rule-of-thumb” when considering the
type of composite and fiber architecture to be used in a component with off-axis stresses.
Implications for Architecture Design of MI SiC/SiC Components From the observations of this study, one can summarize several constituent and
architectural guidelines that can be applied to future designs of components fabricated
with ceramic composites in general and non-oxide Syl-iBN MI SiC/SiC composites in
particular where high off-axis strengths are required. It is assumed that the design goals
will be to achieve as high a matrix cracking stress as possible as well as a high ultimate
tensile strength along the principal stress directions within the components.
16
First, the matrix constituent should display a high stiffness and high strain
capability by utilizing a high-modulus composition, such as SiC, and a fabrication
approach that results in as low porosity as possible, such as MI SiC. For the SiC/SiC
composites of this study, the high-modulus low-porosity MI matrix allows the composite
elastic modulus to be fairly independent of architecture and in-plane testing direction.
Furthermore, as is the case with the MI process, the composite fabrication process should
(if possible) result in a residual compressive stress on the matrix critical flaws after final
composite fabrication (see Table I). In contrast to residual stresses caused by thermal
expansion mismatch between the fiber and matrix, the residual stress of the MI process
appears to be independent of temperature up to at least 815oC [24].
Second, the fiber constituent should be as strong as possible in its as-produced
condition and retain a high fraction of this strength after composite fabrication. The on-
axis UTS values for the Sylramic-iBN composites of this study (see Table 1) and other
studies [7] when normalized by the fiber volume fraction are the highest (~2400 MPa)
displayed to date by any woven SiC-based fiber. For off-axis UTS, high fiber strength is
also important for obtaining high fiber load-carrying ability during bending within matrix
cracks. In addition, the fiber should have as high a modulus as possible in order to shift
composite loads away from the matrix flaws and onto the fiber and reduce matrix crack
opening. Also in combination with the interphase coating, the fiber surface conditions
should be such as to provide high interfacial shear to inhibit large crack-bridging fiber
lengths that will both statistically reduce fiber strength within the cracks (gauge length
effect) and allow more fiber bending for off-axis loading. Due to the relatively high
surface roughness of the Sylramic-iBN fiber and the stiffness of the combined iBN/BN
interphase coating, interfacial shear strengths in Sylramic-iBN/BN/SiC systems are
approximately 70 MPa, much higher than observed with other smoother fiber types
and/or carbon interfacial coatings when processed in the same manner.
Third, the geometry and orientation of the fiber architecture must be judiciously
selected in relation to the directions and magnitudes of the principal stresses within the
CMC component. A primary guideline shown in this study is to achieve effective fiber
volume fractions as a high as possible in these principal stress directions, both to reduce
stress on matrix flaws and to increase the stress and strain for ultimate failure. However,
17
as shown here, the conventional approach of putting the primary fiber axes directly along
the principal stress directions may not be required and perhaps should be avoided. For
example for the 0/90 panel aligned at 45o to the primary fiber axes, the AE onset cracking
stress increased from 190 to 220 MPa due in part to removal of minicomposites being
perpendicular to the loading direction. But UTS values decreased significantly from 410
to 242 MPa because of fiber strength loss within open matrix cracks. However, for the
braided panel aligned at a smaller 23o to the primary fiber axes, onset stresses remained
high at ~220 MPa and UTS only degraded to ~350 MPa. Generally it is thought that
high UTS values are desirable for composite materials; but for non-oxide ceramic
composites, such as MI SiC/SiC, structural life degrades in a complex manner above the
cracking stress due to environment ingress through the open matrix cracks. In addition,
above the cracking stress, composite properties such as modulus and thermal conductivity
also degrade in complex and unpredictable ways. Thus today most CMC designers of
non-oxide CMC components that require long service life find it more desirable to
achieve as high a cracking stress as possible in the principal stress directions, but still
retain some comfortable level of ultimate strength. As shown in this study, this goal can
best be achieved by increasing the effective fiber fraction in these directions, but in doing
so, one should attempt to minimize the size and volume fraction of minicomposites
oriented perpendicular to these directions. For those cases where perpendicular
minicomposites cannot be avoided, this and other studies [7, 25] have shown that the
fairly robust mechanistic-based mini-matrix approach can be helpful in understanding
and modeling matrix cracking for a variety of 2D and 3D fiber architectures.
SUMMARY AND CONCLUSIONS A 2D-woven 0/90 and a 2D-braided -67/0/67 Sylramic-iBN reinforced melt-
infiltrated SiC matrix panel when tensile tested in-plane at an angle symmetrically
located between the two primary fiber directions were both shown to exhibit high stress
for the onset of through-thickness matrix cracking. The matrix cracking and deflection
from linearity stresses were actually higher for the off-axis loading condition compared to
2D-woven 0/90 panels loaded in one of the primary fiber directions. For both panels, this
improved cracking behavior can be explained in part by a higher effective fraction of
18
fibers in the loading direction which reduces internal stress on critical matrix flaws for a
given composite stress. For the woven panel, there also existed an absence of weak
minicomposites oriented perpendicular to the loading direction. For the braided panel,
which did have a low fraction of axial minicomposites loaded perpendicular to the
loading direction, the minicomposites were well separated from one another which
prohibited the occurrence of “back-to-back” 90o minicomposites that are the source of
low strength matrix cracks in 2D-woven 0/90 composites with similar tow size. Acoustic
emission measurements on the braided panel also showed that that the onset stress for
through-thickness matrix cracking and the cracking distribution with increasing stress
behaved effectively the same as 2D-woven 0/90 composites when loaded in a primary
fiber direction. Not only does this confirm that the weak minicomposites perpendicular
to the loading direction are the critical source of through-thickness matrix cracks, it
should also enable use of the “minimatrix” approach [7] to model and improve matrix
cracking and DFL stresses of CMC components with braided and other architectures.
In terms of in-plane ultimate tensile strength, the Syl-iBN/MI SiC composites
were found to be superior in both on-axis and off-axis behavior in comparison to other
2D ceramic composites in the literature with either fiber-dominated or matrix-dominated
mechanical behavior. The off-axis behavior can be attributed primarily to the relatively
high modulus and strength of the MI matrix which carries significant load and to the high
strength of the Sylramic-iBN fiber that is retained during composite processing.
ACKNOWLEDGEMENT
We would like to thank Wayne Steffier of Hyper-Therm Composites Incorporated
for provision of the excellent property database of the various CMCs that they fabricate.
REFERENCES
1. J. Aveston, G.A. Cooper, and A. Kelly, “Single and Multiple Fracture,”
Proceedings of the The Properties of Fibre Composites Conference, IPC Science
and Tech. Press, Ltd., Guildford, Surrey, England, pp. 15-24 (1971)
2. C. Cady, F. E. Heredia, and A.G. Evans, “In-Plane Mechanical Properties of
Several Ceramic-Matrix Composites,” J. Am. Ceram. Soc., 78 [8] 2065-78 (1995)
19
3. E.A.V. Carelli, H. Fujita, J.Y. Yang, and F.W. Zok, “Effects of Thermal Aging on
the Mechanical Properties of a Porous-Matrix Ceramic Composite,” J. Am.
Ceram. Soc., 85 [3] 595-602 (2002).
4. J.A. DiCarlo, H-M. Yun, G.N. Morscher, and R.T. Bhatt, "SiC/SiC Composites
for 1200oC and Above" Handbook of Ceramics Composites, ed. N. Bansal,
Chapter 4; pp. 77-98 (Kluwer Academic; NY, NY: 2005)
5. H.M. Yun, J.Z. Gyekenyesi, Y.L. Chen, D.R. Wheeler, and J.A. DiCarlo, “Tensile
behavior of SiC/SiC composites reinforced by treated Sylramic SiC fibers.”
Ceram. Eng. Sci. Proc., 22, pp. 521-531 (2001).
6. G.N. Morscher, “Modal Acoustic Emission of Damage Accumulation in a Woven
SiC/SiC Composite,” Comp. Sci. Tech. 59 687-697 (1999).
7. G.N. Morscher, “Stress-Dependent Matrix Cracking in 2D Woven SiC-fiber
Reinforced Melt-Infiltrated SiC Matrix Composites”, Comp. Sci. Tech., 64 pp.
1311-1319 (2004)
8. ASTM C-1275, “Standard Test Method for Monotonic Tensile Behavior of
Continuous Fiber-Reinforced Advanced Ceramics with Solid Rectangular Cross-
Section Test Specimens at Ambient Temperature,” ASTM, 100 Barr Harbor
Drive, West Conshohocken, PA (2000)
9. S.Kalluri, A. Calomino, and D.N. Brewer, “An Assessment of Variability in the
Average Tensile Properties of a Melt-Infiltrated SiC/SiC Composite,” Cer. Eng.
Sci. Proc., 25 [4] 79-86 (2004)
10. G.N. Morscher and V. Pujar, "Melt-Infiltrated SiC Composites for Gas Turbine
Engine Applications," Proceedings of ASME Turbo Expo 2004: Power for Land,
Sea, and Air, June 14-17, 2004, Vienna, Austria paper no. GT2004-54233
11. G.N. Morscher and J.D. Cawley, “Intermediate Temperature Strength
Degradation in SiC/SiC Composites,” J. European Ceramic Society, vol. 22, no.
14-15, pp. 2777-2788 (2002)
12. B.N. Cox and D.B. Marshall, “Crack Initiation in Fiber-Reinforced Brittle
Laminates,” J. Am. Ceram. Soc., 79 [5] 1181-88 (1996)
13. G.N. Morscher, “Modal Acoustic Emission Source Determination in Silicon
Carbide Matrix Composites,” in Review of Progress in Quantitative
20
Nondestructive Evaluation, eds. D.O. Thompson and D.E. Chimenti, CP 509,
American Institute of Phisics, pp. 383-390 (2000)
14. G.N. Morscher, “Matrix Cracking in Four Different 2D SiC/SiC Composite
Systems”, Published in the 35th International SAMPE Technical Conference
Proceedings (CD), Dayton, OH (2003)
15. R.M. Jones, Mechanics of Composite Materials (Hemisphere Publishing Corp.,
NY: 1975) p. 54
16. G.N. Morscher, “Modeling the Elastic modulus of 2D Woven CVI SiC
Composites”, Comp. Sci. Int., 66 [15] 2804-2814 (2006).
17. F.W. Zok, “Fracture Analysis of Fiber-Reinforced Ceramic Composites,” ASM
Engineered Materials Handbook Vol. 21: Composites pp. 407-418 (2001)
18. N.K. Naik, P.S. Shemekar, and M.V. Hosur, "Failure Behavior of Woven Fabric
Composites," J. Comp. Tech. and Res., vol 13, no. 2 pp 107-16 (1991)
19. P.J. Falzon and I. Herzberg, "Mechanical performance of 2-D braided
carbon/epoxy composites", Comp. Sci. Tech., 58, 253-265 (1998)
20. J.A. Heathcote, X.Y. Gong, J. Yang, U. Ramamurty, and F.W. Zok, "In-Plane
Mechanical Properties of an All-Oxide Ceramic Composite," J. Am. Ceram. Soc.,
82 [10] 2721-2730 (1999)
21. Wayne Steffier, Composite Data Sheets, Hyper-Therm Composites, Inc. (2006)
22. C.S. Lynch and A.G. Evans, "Effects of Off-Axis Loading on the Tensile
Behavior of a Ceramic-Matrix Composite" J. Am. Ceram. Soc., 79 [12] 3113-23
(1996)
23. Unpublished data from NASA’s Enabling Propulsion Materials Program.
24. G.N. Morscher, Unpublished research based on unload-reload tests performed at
815oC
25. G.N. Morscher, H.M. Yun, J.A. DiCarlo, "Matrix Cracking in 3D Orthogonal
Melt-Infiltrated SiC/SiC Composites with Various Z-Fiber Types", J. Am. Ceram.
Soc., 88 [1] 146-153 (2005)
21
Table I: Composite Properties
Panel
2D Architecture
Thick-ness, mm
Total Fiber
Fraction f
Test Angle to Primary Fibers
E, GPa
UTS, MPa
Residual Stress in Matrix,
MPa
A1 8.7 epcm 0/90,8 ply, 5HS, single-tow 2.3 0.39 0o 261 410 -60
A2 7.9 epcm 0/90, 8 ply, 5HS, single-tow 2.0 0.39 0o 250 463 -50
A3 3.95 epcm (2) epi 0/90, 8 ply, 5HS, double-tow 2.1 0.39 0o 202 444 -50
A4 8.7 epcm 45/45,8 ply, 5HS, single-tow 2.4 0.36 45o 233 242 -40
B1 0/+67 Braid, 4 layer,
tri-axial braid, double-tow
1.8 0.32* 23o 240 260
338 366 -60
* Fraction of fibers in the axial direction = 0.06; Fraction of fibers in each of the bias directions = 0.13
Table II: Matrix Cracking Properties
Panel
DFLS,.002% Offset, MPa
DFLS,.005% Offset, MPa
1st AE Stress, MPa
1st Loud AE
Stress, MPa
AE Onset Stress, MPa
No. of Loud events prior to
AE Onset Stress – Tot # Loud Events
Final Matrix Crack
Density, #/mm
Orthogonal Oriented Composites A1 147 174 132 170 190 4 – 141 -- A2 130 173 100 159 182 1 – 141 10.3 A3 135 176 128 138 157 2 – 134 9.0
Off-Axis Oriented Composites A4 210 225 56 197 220 1 – 65 4.0
232 259 83 187 215 2 – 95 4.9 B1 195 231 135 193 210 3 – 134 --
22
Table III: Ultimate Strength Properties of 0/90 Composites in Literature Tested in Orthogonal and 45/45 Orientations Composite Fiber Architecture Ref
. f=2f0 E(0),
GPa UTS(0), MPa
E(45) GPa
UTS(45), GPa
Matrix Dominated Composites Sylramic-MI 5 HS 21 0.34 268 344 258 200 Hi-Nic-MI 5 HS 21 0.34 210 351 169 158 Nic-CVI SiC Plain Weave 2 ~ 0.4 265 255 NA 210 Nic-CVI SiC 8 HS 21 0.36 240 248 183 192 NiC-CAS 0/90 laminate 2 ~ 0.4 136 215 NA 95 Fiber Dominated Composites Nic -C [2] ---------- 2 ~ 0.4 60 320 NA 80 Nic-C [21] 8 HS 21 0.36 70 252 34 76 C-CVI SiC [21] 8 HS 21 0.36 87 324 62 74 C-C [21] 8 HS 21 0.36 101 305 21 70 Al2O3/Mullite 8 HS 20 ~ 0.4 ~ 97 210 50 52 Table IV: Ultimate Strength Properties of Composites in Literature Tested in Multiple Directions Composite Fiber Architecture Ref
. Orientation
f0 or f*
off-axis E, GPa
UTS, MPa
Matrix Dominated Composites Nic-MAS 0/90 laminate 22 0 0.185 130 385 30 0.185 120 147 45 0.37 110 157 Fiber Dominated Composites C – epoxy PW Plain Weave 18 0 0.25 NA 461 15 0.25 NA 274 30 0.25 NA 143 45 0.5 NA 127 C – epoxy braid 0/+45 Axial 19 0 0.15 40.8 417 0/+60 Axial 0 0.11 31.6 318 0/+60 Hoop 30 0.46 49.9 400 0/+45 Hoop 45 0.42 19.8 165
23
(a)
(b) Figure 1. Photographs of composite surface showing fiber orientations and tensile axis for (a) 45/45 panel A4 and (b) 0+67 braid panel B1.
24
Figure 2: Stress-strain curves of off-axis and orthogonally aligned composites with the hysteresis loop removed for clarity. An example of the hysteresis loops for 0/+67 Braid (1) is shown in the inset.
25
0
50
100
150
200
250
0 0.02 0.04 0.06 0.08 0.1
Strain, %
Stre
ss, M
Pa Stress-strain curve
0.002% offset
0.005% offset
Figure 3: DFL-stress construction for a braided specimen. Note, only the low strain portion of the stress-strain curve is plotted.
26
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
0 100 200 300 400 500
Stress, MPa
Nor
m C
um A
E En
ergy
7.9 epcm0/90
-67/0/67 braid tested in 90o
8.7 epcm, 45/45
3.95 epcmdouble-tow
0/90
8.7 epcm 0/90
Figure 4. AE activity versus composite stress.
27
0
2
4
6
8
10
12
0 100 200 300 400 500Composite Stress, MPa
Est
imat
ed C
rack
Den
sity
, #/m
m 7.9 epcm; 0/90
8.7 epcm 45/45
3.95 epcmDouble
Tow 0/90
8.7 epcm 0/90
-67/0/67 braid tested in 90o
Figure 5: Estimated matrix crack density with stress based on AE.
28
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
0 100 200 300 400 500
Stress, MPa
Nor
m C
um A
E En
ergy
-65/0/65 braid tested in 90o
8.7 epcm 0/90
1st AE event Braid & 0/90
1st Loud AE event Braid & 0/90
Figure 6: AE events and onset stress determination. The arrows below the x-axis indicate AE onset stress.
29
100
120
140
160
180
200
220
240
0.1 0.15 0.2 0.25 0.3Fiber Fraction in Loading Direction
AE
Mat
rix C
rack
ing
Stre
ss, M
Pa
2D orthogonal [7]2D orthogonal - this study2D double tow orthogonal [7]2D double tow orthogonal this study0/+67 double tow braid (hoop direction) - this study
Figure 7: Effect of fiber fraction in the loading direction on AE matrix cracking (onset) stress for 2D composites with fibers tows oriented perpendicular to the loading direction.
30
Figure 8: Micrograph of a 2D woven 45/45 oriented composite after RT tensile failure.
1 mm
31
0
2
4
6
8
10
12
0 50 100 150 200 250 300
Minimatrix stress, MPa
Estim
ated
Cra
ck D
ensi
ty, #
/mm
model for single-tow 2D woven data (ref. 14)
7.9 epcm single-tow woven (this study)3.95 epcm
double-tow woven- this study- ref. 7 -67/0/67 braid tested in 90o
direction
Lower Bound Upper Bound
Figure 9: Estimated matrix crack density versus minimatrix stress.
32
Figure 10: Micrograph of a triaxial braid composite after RT tensile failure.
33
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
0 10 20 30 40 50Angle of loaded-fibers off axis, degrees
Nor
m. E
ffect
ive
Fibe
r Str
engt
h
Al2O3/mullite [20]Nic/C [2]
C/epoxy PW [18] Syl-iBN/MI (this study)
Syl-iBN/MI Braid (this study)
Syl/MI [22]
Nic/MAS [22]
Nic/CAS [2]HN/MI [22]
Nic/CVI [2]
C/epoxy braid [19]
Nic/CVI[21]
C/C & C/CVI SiC [21]
Nic/PYC[21]
Fiber Axis
Loading Axis
angle
Fiber Dominated
CMC
Matrix Dominated SiC/SiC CMC
Figure 11: Effect of testing direction and composite type on the relative strength retention of the fibers for the composite data in Tables I, III, and IV.